Contact plug for high-voltage devices

ABSTRACT

A high-voltage field effect transistor (HFET) includes a first active layer, a second active layer, and a layer of electrical charge disposed proximate to the first active layer and the second active layer. A gate dielectric is disposed proximate to the second active layer. A contact region in the HFET includes a contact coupled to supply or withdraw charge from the HFET, and a passivation layer disposed proximate to the contact and the gate dielectric. An interconnect extends through the passivation layer and is coupled to the contact. An interlayer dielectric is disposed proximate to the interconnect, and a plug extends into the interlayer dielectric and is coupled to the first portion of the interconnect.

TECHNICAL FIELD

This disclosure relates generally to semiconductor devices, and morespecifically to high voltage heterostructure field effect transistors(HFETs)

BACKGROUND INFORMATION

One type of high voltage field effect transistor (FET) is aheterostructure FET (HFET), also referred to as a high-electron mobilitytransistor (HEMT). HFETs based on gallium nitride (GaN) and other widebandgap nitride III materials can be used with electrical devices inhigh-speed switching and high-power applications (such as power switchesand power converters) due to their high electron mobility, highbreakdown voltage, and high saturation electron velocitycharacteristics. These physical properties allow HFETs to change statessubstantially faster than other semiconductor switches that conduct thesame currents at similar voltages. The materials used in theconstruction of HFETs also allow them to operate at higher temperaturesthan transistors that use traditional silicon-based technology.

BRIEF DESCRIPTION OF THE DRAWINGS

Non-limiting and non-exhaustive examples of the invention are describedwith reference to the following figures, wherein like reference numeralsrefer to like parts throughout the various views unless otherwisespecified.

FIG. 1A is a cross-sectional side view of an example semiconductordevice which may use an asymmetrical plug interconnect structure, inaccordance with an embodiment of the disclosure.

FIG. 1B is a cross-sectional side view of another example semiconductordevice which may use an asymmetrical plug interconnect structure, inaccordance with an embodiment of the disclosure.

FIG. 2 is a cross-sectional side view of an example semiconductor devicewith an asymmetric plug interconnect structure, in accordance with anembodiment of the disclosure.

FIG. 3A is a top down view of an example layout of a semiconductordevice with an asymmetric plug interconnect structure and alternatingvia/plug layout, in accordance with an embodiment of the disclosure.

FIG. 3B is a cross-sectional side view of an example semiconductordevice with an asymmetric plug interconnect structure, in accordancewith an embodiment of the disclosure.

FIG. 4 is a top down view of an example layout of a semiconductor devicewith an asymmetric plug interconnect structure and alternating via/pluglayout, in accordance with an embodiment of the disclosure.

FIG. 5 is a top down view of an example layout of a semiconductor devicewith an asymmetric plug interconnect structure and alternating via/pluglayout, in accordance with an embodiment of the disclosure.

FIG. 6 is an example process flow for fabricating a semiconductor devicewith an asymmetric plug interconnect structure, in accordance with anembodiment of the disclosure.

Corresponding reference characters indicate corresponding componentsthroughout the several views of the drawings. Skilled artisans willappreciate that elements in the figures are illustrated for simplicityand clarity and have not necessarily been drawn to scale. For example,the dimensions of some of the elements in the figures may be exaggeratedrelative to other elements to help to improve understanding of variousembodiments of the present invention. Also, common but well-understoodelements that are useful or necessary in a commercially feasibleembodiment are often not depicted in order to facilitate a lessobstructed view of these various embodiments of the present invention.

DETAILED DESCRIPTION

Examples of an apparatus and method relating to a contact plug for highvoltage devices are described herein. In the following description,numerous specific details are set forth in order to provide a thoroughunderstanding of the present invention. It will be apparent, however, toone having ordinary skill in the art that the specific detail need notbe employed to practice the present invention. In other instances,well-known materials or methods have not been described in detail inorder to avoid obscuring the present invention. In the followingdescription, numerous specific details are set forth to provide athorough understanding of the examples. One skilled in the relevant artwill recognize, however, that the techniques described herein can bepracticed without one or more of the specific details, or with othermethods, components, materials, etc. In other instances, well-knownstructures, materials, or operations are not shown or described indetail to avoid obscuring certain aspects.

Reference throughout this specification to “one embodiment”, “anembodiment”, “one example” or “an example” means that a particularfeature, structure or characteristic described in connection with theembodiment or example is included in at least one embodiment of thepresent invention. Thus, appearances of the phrases “in one embodiment”,“in an embodiment”, “one example” or “an example” in various placesthroughout this specification are not necessarily all referring to thesame embodiment or example. Furthermore, the particular features,structures or characteristics may be combined in any suitablecombinations and/or subcombinations in one or more embodiments orexamples. In addition, it is appreciated that the figures providedherewith are for explanation purposes to persons ordinarily skilled inthe art and that the drawings are not necessarily drawn to scale.

Interconnects and plugs may be used to connect metals separated bypassivation, oxide, and/or interlayer dielectric (ILD) layers. Forexample, interconnects and plugs may be used to couple the ohmiccontacts (e.g., the source and drain) of an HFET to their respectivemetal layers. These metal layers may be disposed above the passivationand ILD layers. The overall thickness of the passivation, oxide, and ILDlayers are generally quite thick in order for the HFET to hold voltagewithout breaking down. In one example, the overall thickness of thepassivation, ILD, and/or oxide layers is at least 3.7 micrometers (μm).

In general, a via hole is formed to deposit interconnect metal above theelectrical contact to the semiconductor material. This via hole isplaced at the center of the ohmic contact and an interconnect isdeposited in the via hole. The plug is then formed in the center of theinterconnect (which is recessed). When the plug is placed at the middleof the contact, the overall depth of the plug may need to be as deep asthe combined thickness of the passivation, ILD, and other oxide layers(e.g., 3.7 μm). One type of plug which may be used is a tungsten plug,also referred to as a W-plug. The depth of the plug is generally limitedto about 2 μm due to process constraints. Accordingly, two plugs (one ontop of the other) may be needed to reach the equivalent thickness ofpassivation, ILD, and other oxide layers. The processing steps requiredto form two stacked plugs may add extra cost to the device as comparedto forming one plug. Also by eliminating the two-step plug process,reliability of the process may be increased.

In examples of the present disclosure, an asymmetrical plug interconnectstructure is used. One or more passivation layers are formed above theohmic contact. A via hole is formed in the one or more passivationlayers such that interconnect metal may be deposited and couple to theohmic contact. The interconnect via is formed off-center from the middleaxis of the ohmic contact. When the interconnect metal is deposited, a“wing” is formed above the one or more passivation layers, and one ormore plugs may be formed above the wing of interconnect metal. Inaddition, the one or more plugs are formed off-center from the centeraxis of the ohmic contact, opposite the hole created by the interconnectvia. As will be shown, the layout of the plugs and via hole mayalternate around the center axis.

FIG. 1A is a cross-sectional side view of an example semiconductordevice 100, which may use an asymmetrical plug interconnect structure.Semiconductor device 100 includes substrate 102, first active layer 104,second active layer 108, gate dielectric 110, gate 112, contacts 114 and116, passivation/interconnect region 118, and planarized surface 120.Also shown in FIG. 1A is layer of electrical charge 106, which may formbetween (or proximate to the interface of) first active layer 104 andsecond active layer 108 due to the bandgap energy difference between thetwo layers. Layer of electrical charge 106 may define the lateralconductive channel. The layer of electrical charge 106 includes atwo-dimensional electron gas (2DEG), since electrons are free to move intwo dimensions but are tightly confined in the third dimension. Further,first active layer 104 is sometimes called a channel layer while secondactive layer 108 is sometimes called the barrier layer or donor layer.

First active layer 104 is disposed over the substrate 102. Second activelayer 108 is disposed on first active layer 104. Gate dielectric layer110 is disposed on second active layer 108. Gate 112 is formed atop gatedielectric layer 110, while contacts 114 and 116 are shown as extendingvertically down through gate dielectric 110 to electrically connect tosecond active layer 108. Contact 114 may be a drain contact whilecontact 116 may be a source contact. As shown, source and drain ohmiccontacts 114 and 116 are laterally spaced-apart, with gate 112 beingdisposed between source and drain contacts 114 and 116.

First active layer 104 is disposed over substrate 102, and substrate 102may be formed from materials such as sapphire (Al₂O₃), silicon (Si), orsilicon carbide (SiC). Various techniques of fabrication may call forlayers of other materials to be disposed between substrate 102 and firstactive layer 120 to facilitate the construction of the device. Firstactive layer 104 may include a first semiconductor material having afirst bandgap. In some examples, first active layer 104 may includesemiconductor materials containing nitride compounds of group IIIelements. For example, first active layer 104 may be grown or depositedon substrate 102 and may include GaN.

Second active layer 108 may include a second semiconductor material(e.g., aluminum gallium nitride (AlGaN)) having a second bandgap that isdifferent than the first bandgap of first active layer 104. In otherexamples, different group III nitride semiconductor materials, such asaluminum indium nitride (AlInN) and aluminum indium gallium nitride(AlInGaN), may be used for second active layer 108. In other examples,second active layer 108 may include a non-stoichiometric compound (e.g.,a group III nitride semiconductor material, such as AlXGa1-XN, where0<X<1). In such materials, the ratios of the elements are not easilyrepresented by ordinary whole numbers. Second active layer 108 may begrown or deposited on first active layer 104.

Gate dielectric 110 may include silicon nitride (SiN) or Si₃N₄. In otherexamples, different nitride-based compounds, such as carbon nitride (CN)or boron nitride (BN), may be used for gate dielectric 110. AlthoughFIG. 1A illustrates a single gate dielectric 110, it should beappreciated that multiple gate dielectric layers may be used, and caninclude other oxide materials such as aluminum oxide (Al₂O₃), hafniumoxide (HfO₂), zirconium Oxide (ZrO₂), etc. Gate dielectric 110 may bedeposited through atomic layer deposition (ALD), or the like.

In the depicted example, gate 112 contacts the gate dielectric 110 andmay include a gold nickel (NiAu) stack. In another example, gate 112 mayinclude a titanium gold (TiAu) stack or molybdenum gold (MoAu) stack. Inoperation, gate 112 controls the forward conduction path between drainterminal (contact 116) and source terminal (contact 114). Contact 116and contact 114 may include titanium (Ti), molybdenum (Mo), aluminum(Al), or gold (Au). Above the contacts 114/116 and drain 112 is apassivation/interconnect region 118. The passivation/interconnect region118 may include one or more passivation layers, oxide layers, andinterlayer dielectrics (ILDs). The thickness of thepassivation/interconnect region 118 is shown as Z1 121. In one example,the thickness Z1 121 may be 3.7 μm or more. Further, metal layers may bedisposed on planarized surface 120 at the top ofpassivation/interconnect region 118. As will be further discussed, theasymmetric plug interconnect structure (not shown) is within thepassivation/interconnect region 118 and couples to contacts 114 and 116.

FIG. 1B is a cross-sectional side view of an example semiconductordevice 101, which may use an asymmetrical plug interconnect structure.Semiconductor device 101 includes substrate 102, first active layer 104,second active layer 108, gate dielectric 110, gate 112, ohmic contacts114 and 116, passivation/interconnect region 118, and planarized surface120. The structure shown for semiconductor device 101 of FIG. 1B issimilar to semiconductor device 100 shown in FIG. 1A; however,semiconductor device 101 may be formed using a gold-free process. Itshould be appreciated that similarly named and numbered elements coupleand function as described above; however, in FIG. 1B, ohmic contacts 114and 116 extend through the gate dielectric 110, second active layer 108,first active layer 104, and intercept electrical charge layer 106. AnOhmic contact forms where the metal of contacts 114/116 intercepts theelectrical charge layer 106. Gate 112 may include titanium (Ti),titanium nitride (TiN), and aluminum copper (AlCu), while contacts 114and 116 may include titanium (Ti), aluminum (Al) or titanium nitride(TiN). As shown, a portion of contacts 114 and 116 sits atop the secondactive layer 108, while another portion of contacts 114 and 116 extendsthrough second active layer 108, first active layer 104, and electricalcharge layer 106. The width of the portion of contacts 114 and 116 thatextends through the second active layer 108, first active layer 104, andthe electrical charge layer 106, is substantially 2-10 μm. The length ofthe portion of contacts 114 and 116, that sits atop second active layer108, is substantially 0.5 μm. As shown, each contact 114 and 116 has twoportions that sit atop second active layer 108.

FIG. 2 is a cross-sectional side view if an example semiconductor device200 with an asymmetric plug interconnect structure. Semiconductor device200 may include active device 203 (e.g., a simplified view of thesemiconductor structure shown in FIGS. 1A and 1B, including the firstand second active layers, e.g., GaN/AlGaN, and the electrical chargelayer, e.g., 2DEG), gate dielectric 210, contact 216, passivation layer222, silicon dioxide remnant 224, interlayer dielectric (ILD) 226,interconnect metal 228, and plugs 230 and 232. Further shown in FIG. 2are thickness Z1 221, axis A 238, via footprint 240, distance d1 242,distance d2 243, and depth Z2 248. As illustrated, the asymmetric pluginterconnect structure includes interconnect 228 and plugs 230 and 232.

In the illustrated example, contact region (e.g., the structure ofmetals and semiconductors used to contact active device 203) includescontact 216 extending through gate dielectric 210 and second activelayer, into the first active layer. Contact 216 may be coupled to thelayer of electrical charge (see e.g., layer of electrical charge 106 inFIGS. 1A and 1B). Passivation layer 222 is disposed proximate to contact216 and gate dielectric 210, and at least part of contact 216 isdisposed between passivation layer 222 and the second active layer (inactive device 203). In some examples, contact 216 forms an ohmic contactwith active device 203. More specifically, contact 216 is electricallycoupled to supply/withdraw electrons from the electrical charge layer(e.g., electrical charge layer 106 of FIG. 1A). Interconnect 228 extendsthrough passivation layer 222, and is coupled to contact 216. Asillustrated, a first portion of interconnect 228 (e.g., the “wing”portion of interconnect 228 that is disposed on, and substantiallycoplanar with, passivation layer 222) is disposed so that passivationlayer 222 is positioned between the first portion of interconnect 228and the second active layer. Additionally, the first portion ofinterconnect 228 is substantially laterally coextensive with a firstside of contact 216. Conversely, a second portion of interconnect 228extends through passivation layer 222 to electrically couple to contact216. As shown, the second portion of interconnect 228 substantiallyforms a trapezoid, where a first parallel side of the trapezoid includesmetal and is coupled to contact 216. As shown, nonparallel sides of thetrapezoid include the metal and are in contact with passivation layer222. The second parallel side of the trapezoid includes an oxide (e.g.,remnant 224) and is larger than the first parallel side.

In the depicted example, interlayer dielectric 226 is disposed proximateto interconnect 228, and the first portion of interconnect 228 isdisposed between interlayer dielectric 226 and passivation layer 222.Plug 230 and plug 232 (i.e., a plurality of plugs) extend intointerlayer dielectric 226, and are coupled to the first portion (e.g.,the “wing”) of interconnect 228.

In one example, contact 216 (which may include metal) partially sits ontop of the gate dielectric layer 210 to form an Ohmic contact with theelectrical charge layer in a gold-free process. However, contact 216 cansit on top of the active device 203 when a gold-based process is used.

In another or the same example, passivation layer 222 is disposed abovethe gate dielectric layer 210, contact 216. Passivation layer 222 mayinclude a nitride-based compound, such as silicon nitride SiN. Althoughonly one passivation layer 222 is shown, multiple passivation layers maybe used. Multiple passivation layers may also be interlaced with oxidelayers or the like. Passivation/oxide/ILD layers may be deposited usingplasma enhanced chemical vapor deposition (PECVD).

In one example, interconnect 228 is disposed above contact 216 andextends through passivation layer 222. Via footprint 240 defines thesidewall/trench of interconnect metal 228. As shown, via footprint 240is offset from the center of the contact 216 (axis A 238). The center ofvia footprint 240 is offset from axis A 238 by the distance d2 243. Thewidth of the footprint is shown as distance d1 242. The width d1 242 ofthe via footprint 240 defines the bottom width of the trench. The top ofthe trench is wider than the width d1 242 because of the formationprocess of the via. The metal used for interconnect 228 also forms a“wing” (e.g., the first portion of interconnect 228) on the oppositeside of the via along axis A 238. The wing of interconnect 228 is themetal portion of the interconnect 238 which sits above the passivationlayer 222. Interconnect 228 is used to couple the contact 216 to othermetal layers, which are disposed on the planarized surface 220 (alongwith plugs 230 and 232).

In another or the same example, silicon dioxide remnant 224 is disposedabove the passivation layer 222 and fills the via/trench created by theinterconnect metal 228. Tetraethyl orthosilicate (TEOS) may be used todeposit the silicon dioxide to form silicon dioxide remnant 224.However, the silicon dioxide could be deposited using saline-based ordisaline-based processes. The silicon dioxide formed using TEOS isgenerally of lower density and may be utilized for electrical blockage.Similarly, interlayer dielectric (ILD) 226 (e.g., an oxide) is disposedabove the TEOS (silicon oxide) remnant 224. The top of interlayerdielectric oxide 226 is planarized to result in planarized surface 220.

In one example, plugs 230 and 232 are disposed through the ILD 226 tocontact interconnect 228. Plugs 230 and 232 are attached to interconnect228 and are disposed in the planarized surface 220 (to couple to othermetals layers). In one example, plugs 230 and 232 are tungsten plugswith depth Z2 248. The depth of plugs 230 and 232 are generally limitedby the process. In one example, the depth Z2 248 of plug 230 issubstantially double the width of plug 230. The total thickness fromgate dielectric 210 to planarized surface 220 is shown as thickness Z1221. In devices where the via footprint is centered in the ohmiccontact/along axis A, the plug would need to be deep enough to traversethe entirety of thickness Z1 221. As shown, plugs 230 and 232 are deepenough to reach the wing of interconnect 228 at approximately the depthof the ILD oxide 226, which is much smaller than the thickness Z1 221and shown as depth Z2 248. This allows simplification of themanufacturing process for the semiconductor device 200.

FIG. 3A is a top down view of an example layout of semiconductor device300 with an asymmetric plug interconnect structure and alternatingvia/plug layout. Semiconductor device 300 includes a portion of activedevice 303, contact region 399, an ohmic contact/metal drain footprint314, ohmic contact/metal source footprint 316, plug footprints 331A,331B, and 331C for the source, plug footprints 333A, 333B, and 333C forthe drain, via footprints 340A, 340B, and 340C for the source, and viafootprints 341A, 341B, and 341C for the drain. Further shown in FIG. 3Ais also the distance d1 342, which is one example of the width of thevia footprint for the drain.

As shown, contact region 399 is included in at least one of a sourceregion (e.g., source contact 316) or a drain region (e.g., drain contact314) of the HFET—in the depicted example, multiple contact regions398/399 are included in both the source and drain electrodes and arevertically (with respect to the page orientation) aligned. Also, plugs331C in contact region 399 are disposed closer to the first side (righthand side of page) of the HFET than second plugs 331B included in asecond contact region 398 which are disposed closer to the second side(left hand side) of the HFET. In other words, an orientation of secondcontact region 398 is a mirror image of contact region 399.

Also, as shown in the depicted example, plugs 331A/331B/331C have awidth and a length, where the length of the plug is larger than thewidth. As shown previously in other figures, the height of plugs331A/331B/331C is greater than or equal to a thickness of the interlayerdielectric.

The depicted example outlines (large dashed box) a portion of the activedevice: active area 303 (e.g., first and second active layer and theelectrical charge layer). Similarly, a first solid line illustrates thetop down outline of drain contact 314 (e.g., the ohmic contact/metal forthe drain). As shown, drain contact 314 is generally finger shaped. Asecond solid line illustrates the top down outline of source contact 316(e.g., the ohmic contact/metal for the source). As shown, source contact316 is generally finger shaped.

Via footprint for 340A, 340B, 340C and plug outline 331A, 331B, and 331Cfor the source 316 are also depicted. As shown, the top down outline forthe grouping of plugs 331A, 331B, and 331C is bar shaped. For theexample shown, each grouping of plugs 331A, 331B, and 331C includes twobars. To aid in symmetry of current flow between the drain contact 314and source contact 316, the via footprints 340A, 340B, and 340C arealternated with the grouping of plugs 331A, 331B, and 331C. Via outline340A is on the left side of source contact 316 while grouping of plugs331A is on the right side of source contact 316. Conversely, via outline340B is on the right side of source contact 316 while the grouping ofplugs 331B is on the left side (e.g., a mirror image of plugs 331A).Further, via outline 340C is on the left side while the grouping ofplugs 331C is on the right side of source contact 316. This mirroredpattern may continue for the entire length of the source contact 316.

In the depicted example, cross-section B-B′ is also shown across viafootprint 340A and the grouping of plugs 331A. The example semiconductordevice 200 shown in FIG. 2 may be one example of the semiconductordevice in the cross-section B-B′.

Via footprint for 341A, 341B, 341C and plug outline 333A, 333B, and 333Cfor the drain contact 314 are also depicted. As shown in top down view,plugs 333A, 333B, and 333C are bar shaped. Each grouping of plugs 333A,333B, and 333C includes three bars. In general, the width of draincontact 314 is wider than the width of source contact 316. Accordingly,more plugs may be included in drain contact 314. To aid in symmetry ofcurrent flow between drain contact 314 and source contact 316, the viafootprints 341A, 341B, 341C are alternated with the grouping of plugs333A, 333B, and 333C. Via outline 341A is on the left side of draincontact 314 while grouping of plugs 333A is on the right side of sourcecontact 316. Conversely, while via outline 341B is on the right side ofdrain contact 314, while the grouping of plugs 333B is on the left side.Further, via outline 341C is on the left side while grouping of plugs333C is on the right side of drain contact 314. This pattern may berepeated for the entire length of drain 314. The cross-section alongC-C′ of the drain is shown in FIG. 3B.

FIG. 3B is a cross-sectional side view of another example semiconductordevice 301 with an asymmetric plug interconnect structure. Semiconductordevice 301 is cut along the cross-section C-C′ in FIG. 3A and includesan asymmetric plug interconnect structure. The structure includes activedevice 303, gate dielectric 310, ohmic contact 314, passivation layer322, silicon dioxide (TEOS) remnant 324, interlayer dielectric (ILD)326, interconnect metal 328, and plugs 330, 332 and 334. Further shownin FIG. 3B are thickness Z1 321, depth Z2 348, axis A 338, via footprint341, distance d1 342, d2 343, d3 344, d4 345, d5 346, and d6 347. Asshown, the active device 303 may include the first and second activelayers and electrical charge layer discussed in connection with FIGS. 1Aand 1B. For the example shown, the asymmetric plug interconnectstructure includes interconnect 328 and plugs 330, 332, and 334.Similarly named and numbered elements couple and function as describedabove; however, three plugs (330, 332, and 334) are illustrated insteadof the two plugs shown in FIG. 2.

It is appreciated that axis A 338 represents the center of ohmic contact314. Depth Z1 321 represents depth from the planarized surface 320 tothe gate dielectric layer 310. Depth Z2 348 represents depth of plugs330, 332, 334, or the distance from the planarized surface 320 to theTEOS derived silicon oxide 324. The opening width of plugs 330, 332, 334(shown as distance d5 346) is substantially half the depth of the plugs330, 332, 334 (shown as depth Z2 348); d5=½ Z2. Distance d1 342represents the width of the via used to create the trench forinterconnect 328. The minimum for distance d1 342 may be substantially 2μm. Distance d2 343 represents the distance between the center of thevia for interconnect 328 and axis A 338. In one example, distance d2 343is substantially ¼ of distance d3 334. Distance d3 334 represents thelength of contact 314. As shown, interconnect 328 may have substantiallythe same length of contact 314. However, it should be appreciated thatthe “wing” of interconnect 328 may extend beyond distance d3 334 to formthe field plate for contact 314. Distance d4 345 represents the distancebetween the end of the wing of interconnect 328 and plug 334. Thisdistance may be determined by the processing steps used to fabricate thearchitectures depicted. Distance d4 345 may be substantially zero andplug 334 starts at the edge of the “wing” of interconnect 328. However,distance d4 345 is dependent on the topography capability of the processto deposit the plugs. Distance d4 345 may be 0.5 μm. Distance d5 346represents the width of the plug opening. Plugs 330, 332, 334 are widerat the top (planarized surface 320) and taper towards the bottom. In oneexample, the ratio of the depth of the plug (Z2 348) to the width of theplug opening at the planarized surface 320 is substantially two. Inother words, distance d5 346 is substantially half of the depth Z2 348.In one example, the distance d5 346 is substantially 1 μm. Distance d6347 represents the distance between each plug. In one example, thedistance is substantially 0.6 μm.

FIG. 4 is a top down view of another example layout of semiconductordevice 400 with an asymmetric plug interconnect structure andalternating via/plug layout. Semiconductor device 400 includes a portionof the active device 403, ohmic contact/metal drain footprint 414, ohmiccontact/metal source footprint 416, contact region 499, plug footprints431A, 431B, and 431C for the source, plug footprints 433A, 433B, and433C for the drain, via footprints 440A, 440B, and 440C for the source,and via footprint 441A, 441B, and 441C for the drain. Further shown inFIG. 4 is distance d1 442, which is one example of the width of the viafootprint for source contact 416.

FIG. 4 is similar to FIG. 3A; however, instead of a long continuous barfor the plugs, the plugs shown include a grouping of circles in a line.The cross-section shown in FIG. 2 may be one example of semiconductordevice 400 at cross-section D-D′. The cross-section shown in FIG. 3B maybe one example of semiconductor device 400 at cross-section E-E′.

FIG. 5 is a top level view of an example layout of semiconductor device500 with an asymmetric plug interconnect structure and alternatingvia/plug layout. Semiconductor device 500 includes a portion of activedevice 503, ohmic contact/metal drain footprint 514, ohmic contact/metalsource footprint 516, contact region 599, plug footprint 531 for thesource, plug footprint 533 for the drain, via footprints 540A and 540Bfor the source, and via footprints 541A and 541B for the drain. Furthershown in FIG. 5 is distance d1 542, which is one example of the width ofthe via footprint for the source contact 516.

FIG. 5 is similar to FIG. 3A and FIG. 4, however, the via and plugsalternate in a different lateral direction than the via and plugs shownin FIG. 3A and FIG. 4. The cross-section of the semiconductor device 500is similar to the cross-section of the semiconductor devices shown inFIG. 2 and FIG. 3B; however, the device shown in FIG. 5 may have moreplugs. For the example shown, there may be six plugs illustrated in thecross-section on the wing of the asymmetrical plug interconnectstructure.

FIG. 6 is an example process flow for fabricating a semiconductor devicewith an asymmetric plug interconnect structure. One of ordinary skill inthe art having the benefit of the present disclosure will appreciatethat the process flow depicted can occur in any order and even inparallel. Additionally, blocks may be added to, and removed from, theprocess flow in accordance with the teachings of the present disclosure.

Block 602 illustrates forming the active device including the first andsecond active layer, and the electrical charge layer. The gatedielectric may also be formed. In some examples, the gate dielectric isdisposed on a surface of the semiconductor material, and the secondactive layer is disposed between the gate dielectric and the firstactive layer.

Block 604 shows forming a via for an ohmic contact to the semiconductormaterial. In one example, the via may be etched using inductivelycoupled plasma (ICP), or the like. The trench that is etched may extendthrough the gate dielectric, second active layer, and into the firstactive layer.

Block 606 depicts depositing the metal to form a contact. In oneexample, a metal is deposited using physical vapor deposition (PVD) andthe metal lines the walls of the trench formed in block 604. The metalmay extend from the gate oxide to the first active layer.

Block 608 illustrates annealing the metal of the contact between themetal and semiconductor using rapid thermal annealing (RTA) or the like.

Block 610 shows depositing passivation and interlayer dielectrics(ILDs). These layers may be deposited using plasma-enhanced chemicalvapor deposition (PECVD).

Block 612 depicts forming a via for the interconnect. This may beachieved by etching a trench through the passivation layer, and thetrench may reach the contact.

Block 614 illustrates depositing the metal for the interconnect in thevia/trench formed in block 612. In one example, interconnect metal isdeposited using physical vapor deposition (PVD). The metal may bedeposited in the trench, and on the passivation layer, to form theinterconnect. The metal may line the walls of the trench (in a secondportion of the interconnect), and (in a first “wing” portion of theinterconnect) the metal is substantially coplanar with the passivationlayer. The interconnect may extend through the first passivation layerand electrically couple to the first contact. The first portion of theinterconnect is disposed on the passivation layer so that thepassivation layer is disposed between the first portion of theinterconnect and the second active layer. It should be appreciated thatin some examples, blocks 610, 612, and 614 may be repeated for multiplepassivation layers.

Block 616 illustrates depositing silicon oxide using tetraethylorthosilicate (TEOS). Depositing tetraethyl orthosilicate (TEOS) on theinterconnect may fill a void in the center of the second portion of theinterconnect. However, silicon dioxide could be deposited using salineor disilane.

Block 618 shows planarizing residual silicon oxide from the TEOSdeposition. In one example, planarization may be done using a resistetch back (REB) process or chemical-mechanical planarization (CMP)process. Once planarized, what is left on the semiconductor device maybe referred to as a TEOS-based silicon dioxide.

Block 620 depicts depositing the interlayer dielectric proximate to theinterconnect. In one example, the first portion of the interconnect isdisposed between the interlayer dielectric and the passivation layer.

Block 622 illustrates forming the plug by etching, depositing, and thenplanarizing the top surface of the plug. In some examples, the trenchthat is etched may have a width, a length, and a height, where thelength of the trench is larger than the width, and the height is equalto a thickness of the interlayer dielectric. Inductively coupled plasma(ICP) may be used to etch the plug and deposit the plug material (e.g.,tungsten) while CMP may be used to planarize the plug. Planarizing maybe used to remove residual metal disposed on the surface of theinterlayer dielectric.

One of ordinary skill in the art, having the benefit of the presentdisclosure, will appreciate that the process flow depicted may berepeated many times to form a plurality of contact regions including theone or more contact regions. In some of these examples, a first plug maybe disposed closer to a first side of the HFET than a second plug in asecond contact region, and the second plug is disposed closer to asecond side, opposite the first side, of the HFET. In other words, theorientation of the second contact region may be a mirror image of thefirst contact region.

The above description of illustrated examples of the present invention,including what is described in the Abstract, are not intended to beexhaustive or to be limitation to the precise forms disclosed. Whilespecific embodiments of, and examples for, the invention are describedherein for illustrative purposes, various equivalent modifications arepossible without departing from the broader spirit and scope of thepresent invention. Indeed, it is appreciated that the specific examplevoltages, currents, frequencies, power range values, times, etc., areprovided for explanation purposes and that other values may also beemployed in other embodiments and examples in accordance with theteachings of the present invention.

These modifications can be made to examples of the invention in light ofthe above detailed description. The terms used in the following claimsshould not be construed to limit the invention to the specificembodiments disclosed in the specification and the claims. Rather, thescope is to be determined entirely by the following claims, which are tobe construed in accordance with established doctrines of claiminterpretation. The present specification and figures are accordingly tobe regarded as illustrative rather than restrictive.

What is claimed is:
 1. A high-voltage field effect transistor (HFET),comprising: a first active layer including a first semiconductormaterial having a first bandgap; and a second active layer including asecond semiconductor material having a second bandgap; a layer ofelectrical charge formed proximate to the first active layer and thesecond active layer in response to a difference in bandgap energybetween the first bandgap and the second bandgap; a gate dielectricdisposed proximate to the second active layer, wherein the second activelayer is disposed between the first active layer and the gatedielectric; and a contact region including: a contact coupled to supplyor withdraw charge from the HFET; a passivation layer disposed proximateto the contact and the gate dielectric, wherein at least part of thecontact is disposed between the passivation layer and the second activelayer; an interconnect extending through the passivation layer andcoupled to the contact, wherein a first portion of the interconnect isdisposed on the passivation layer so that the passivation layer isdisposed between the first portion of the interconnect and the secondactive layer; an interlayer dielectric disposed proximate to theinterconnect, wherein the first portion of the interconnect is disposedbetween the interlayer dielectric and the passivation layer; and a plugextending into the interlayer dielectric and coupled to the firstportion of the interconnect, wherein the plug is disposed off of acenter axis of the interconnect.
 2. The HFET of claim 1, wherein asecond portion of the interconnect extends through the passivationlayer, and the first portion is substantially coplanar with thepassivation layer.
 3. The HFET of claim 2, wherein the second portion ofthe interconnect substantially forms a trapezoid, wherein a firstparallel side of the trapezoid includes metal and is coupled to thecontact, wherein nonparallel sides of the trapezoid include the metal,and wherein a second parallel side of the trapezoid includes an oxideand is larger than the first parallel side.
 4. The HFET of claim 3,wherein the passivation layer is disposed between the contact and thefirst portion of the interconnect, and wherein the first portion of theinterconnect is substantially laterally coextensive with a first side ofthe contact.
 5. The HFET of claim 2, further comprising a plurality ofplugs, including the plug, extending into the interlayer dielectric andcoupled to the first portion of the interconnect.
 6. The HFET of claim5, wherein the contact region is included in at least one of a sourceregion or a drain region of the HFET.
 7. The HFET of claim 6, furthercomprising a plurality of contact regions, including the contact region,aligned in the semiconductor material in the at least one of the sourceregion or the drain region of the HFET.
 8. The HFET of claim 7, whereinthe plug in the contact region is disposed closer to a first side of theHFET than a second plug in a second contact region in the plurality ofcontact regions, wherein the second plug is disposed closer to a secondside, opposite the first side, of the HFET.
 9. The HFET of claim 8,wherein an orientation of the second contact region is a mirror image ofthe contact region.
 10. The HFET of claim 1, wherein the plug has awidth, a length, and a height, wherein the length of the plug is largerthan the width, and wherein the height is greater than or equal to athickness of the interlayer dielectric.
 11. The HFET of claim 1, whereinthe first portion of the interconnect includes a wing structure disposedoff of the center axis of the interconnect.
 12. The HFET of claim 1,wherein the plug is disposed away from a recess in the interconnect.